On fractional order differential equations model for nonlocal epidemics

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Physica A 379 (2007) 607–614 www.elsevier.com/locate/physa

On fractional order differential equations model for nonlocal epidemics E. Ahmeda, A.S. Elgazzarb,c, a

Mathematics Department, Faculty of Science, Mansoura University, 35516 Mansoura, Egypt Mathematics Department, Faculty of Science, Al-Jouf University, P.O. Box 2014, Sakaka, Al-Jouf, Saudi Arabia c Mathematics Department, Faculty of Education, 45111 El-Arish, Egypt

b

Received 17 June 2006 Available online 16 February 2007

Abstract A fractional order model for nonlocal epidemics is given. Stability of fractional order equations is studied. The results are expected to be relevant to foot-and-mouth disease, SARS and avian flu. r 2007 Elsevier B.V. All rights reserved. Keywords: Fractional order differential equations; Stability; Applications to nonlocal epidemic models

1. Introduction Recently three major epidemic diseases have occurred namely foot-and-mouth disease, severe acute respiratory syndrome (SARS) and avian (bird’s) flu. Hopefully this will increase the awareness of modeling infectious diseases spreading that is an important topic in mathematical biology [1]. There are different approaches to this topic, e.g. ordinary differential equations, difference equations, partial differential equations and coupled map lattice. Here we use fractional order differential equations (FOD). The reason is that FOD are naturally related to systems with memory which exists in most biological systems. Also they are closely related to fractals which are abundant in biological systems. Consider the following evolution equation [2]: Z t df ðtÞ 2 ¼ l kðt  t0 Þf ðt0 Þ dt0 . dt 0 If the system has no memory then k(tt0 ) ¼ d(tt0 ), and one gets f(t) ¼ f0 exp(l2t). If the system has an ideal memory, then ( 1 if tXt0 0 kðt  t Þ ¼ , 0 if tot0 Corresponding author. Mathematics Department, Al-Jouf University, P.O. Box 2014, Sakaka, Al-Jouf, Saudi Arabia.

E-mail address: [email protected] (A.S. Elgazzar). 0378-4371/$ - see front matter r 2007 Elsevier B.V. All rights reserved. doi:10.1016/j.physa.2007.01.010

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R1 hence fEf0 cos lt. Using Laplace transform L½f  ¼ 0 f ðtÞ expðstÞ dt, one gets L[f] ¼ 1 if there is no memory and L[f] ¼ 1/s if there is ideal memory hence the case of non-ideal memory is expected to be given by L[f] ¼ 1/sa, 0oao1. In this case the above equation becomes Z t df ðtÞ 1 ¼ ðt  t0 Þa1 f ðt0 Þ dt0 , dt GðaÞ 0 where G(a) is the Gamma function. This system has the following solution: f ðtÞ ¼ f 0 E aþ1 ðl2 taþ1 Þ, where Ea(z) is the Mittag–Leffler function given by E a ðzÞ ¼

1 X

zk . Gðak þ 1Þ k¼0

It is direct to see that E1(z) ¼ exp(z), E2(z) ¼ cos z. Following a similar procedure to study a random process with memory, one obtains the following fractional evolution equation: qaþ1 Pðx; tÞ X ð1Þn qn ½K n ðxÞPðx; tÞ ¼ ; qtaþ1 qxn n! n

0oao1,

where P(x, t) is a measure of the probability to find a particle at time t at position x. We expect that the above result will be relevant to many complex adaptive systems and to systems where fractal structures are relevant since it is argued that there is a strong relevance between fractals and fractional differentiation [3]. For the case of fractional diffusion equation the results are qaþ1 Pðx; tÞ q2 Pðx; tÞ ¼ D ; qtaþ1 qx2

Pðx; 0Þ ¼ dðxÞ;

qPðx; 0Þ ¼ 0, qt

then 1 P ¼ pffiffiffiffi M 2 Dtb Mðz; bÞ ¼



  jxj pffiffiffiffi ;b ; D tb

b¼

aþ1 , 2

1 X

ð1Þn zn . n!Gðbn þ 1  bÞ n¼0

For the case of no memory a ¼ 0 ) M(z; 1/2) ¼ exp(z2/4). The paper is organized as follows: in Section 2, we study the stability of FOD. The stability conditions are derived and several examples are given. The stability conditions for some fractional order differential coupled map lattices are concluded in Section 3. Applications to nonlocal epidemics is introduced in Section 4. The stability conditions for the disease-free state are discussed. Some conclusions are presented in Section 5.

2. Stability of fractional order differential equations [4–6] Consider the following system: Da xðtÞ ¼ f ðx; yÞ; Da yðtÞ ¼ gðx; yÞ; a 2 ½0; 1Þ,

(1)

where the fractional derivative in Eq. (1) is in the sense of Caputo. The equilibrium solutions are defined by f(xeq, yeq) ¼ 0, g(xeq, yeq) ¼ 0 and it is locally asymptotically stable if all the eigenvalues l of the Jacobian

ARTICLE IN PRESS E. Ahmed, A.S. Elgazzar / Physica A 379 (2007) 607–614

" matrix A ¼

qf =qx

qf =qy

qg=qx

qg=qy

609

# evaluated at the equilibrium point satisfies the following condition [4,5]:

  argðlÞ4 ap . 2 The condition in Eq. (2) poses an interesting question namely: What are the conditions that all the roots of the polynomial equation PðlÞ ¼ 0; PðlÞ ¼ ln þ a1 ln1 þ a2 ln2 þ    þ an satisfy Eq. (2) where all the coefficients in Eq. (3) are real? For a ¼ 1, the solution is the Routh–Hurwitz conditions [7]     a1 1 0      a1 1      a1 40;  40;  a3 a2 a1 40; . . . .    a3 a2   a5 a4 a3 

(2)

(3)

(4)

For aA[0, 1), these conditions are sufficient but not necessary. Since most biologically interesting systems are 1,2 and 3-dimensions, we will study the problem (3) for n ¼ 1, 2, 3. Definition 1. The discriminant D(f ) of a polynomial f ðxÞ ¼ xn þ a1 xn1 þ a2 xn2 þ    þ an is defined by D( f ) ¼ (1)n(n1)/2R( f, f 0 ), where f 0 is the derivative of f, if g(x) ¼ xn+b1xl1+b2xl2+?+bl, R(f, g) is the determinant of the corresponding Sylvester (n+l)(n+l) matrix. The Sylvester matrix is formed by filling the matrix beginning with the upper left corner with the coefficients of f (x), then shifting down one row and one column to the right and filling in the coefficients starting there until they hit the right side. The process is then repeated for the coefficients of g (x). Using the results of Ref. [3], if D( f )40(o0) then there is an even (odd) number of pairs of complex roots for the equation f(x) ¼ 0. For n ¼ 3, this implies that D (f)40, and all the roots are real while D (f)o0 implies that there is only one real root and one complex root and its complex conjugate. For n ¼ 3, we have Dðf Þ ¼ 18a1 a2 a3 þ ða1 a2 Þ2  4a3 a31  4a32  27a23 . Proposition 1. (i) For n ¼ 1, the condition for (3) is a140. (ii) For n ¼ 2, the conditions for (3) are either Routh–Hurwitz conditions or  0qffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffi1   4a2  ða1 Þ2  ap  A 4 . a1 o0; 4a2 4ða1 Þ2 ; tan1 @  2 a1  

(5)

(iii) For n ¼ 3, if the discriminant of P(l), D (P) is positive, then Routh–Hurwitz conditions are the necessary and sufficient conditions for (3) i.e. a1 40; a3 40; a1 a2 4a3

if DðPÞ40.

(6)

(iv) If D(P)o0, a1X0, a2X0, a340, ao2/3, then condition (3) is satisfied. Also if D(p)o0, a1o0, a2o0, a42/3, then all roots of P(l) ¼ 0 satisfies |arg(l)|oap/2. (v) If D(P)o0, a140, a240, a1a2 ¼ a3 then condition (3) is satisfied for all aA[0,1). (vi) For general n, an40 is a necessary condition for condition (3) to be satisfied. (vii) If 8l, P(l) ¼ P(l) then define x ¼ l2 and Routh–Hurwitz conditions for the resulting polynomial in x are necessary conditions for (3) for all aA[0,1).

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R0 R1 (viii) For n41, the necessary and sufficient condition for (3) is 1 dz=PðzÞjC1 þ 0 pdz=PðzÞj C2 ¼ 0, where C1 ffiffiffiffiffiffiffi is the curve z ¼ x(1i tan ap/2) and C2 is the curve z ¼ x(1+i tan ap/2), i ¼ 1. qffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffii h Proof. Case (i) is obvious. For (ii), the two roots are l ¼ a1  ða21  4a2 Þ =2. If both roots are real or complex conjugates with negative real parts then condition (3) is equivalent to the Routh–Hurwitz case. If the two roots are complex conjugate with positive real parts, then the two roots become l ¼  qffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffi 2 a1  i 4a2  ða1 Þ =2 and one gets Eq. (5). To prove (iii) not that if n ¼ 3, D (p)40, then all the roots of p(l) ¼ 0 are real hence Routh–Hurwitz conditions are both necessary and sufficient for (3). To prove (iv) not that if n ¼ 3, D (P)40, then the roots of P(l) ¼ 0 are one real and a complex conjugate pair thus pðlÞ ¼ ðl þ bÞðl  b  igÞðl  b þ igÞ ) a1 ¼ b  2b; a2 ¼ b2 þ g2  2bb; a3 ¼ bðb2 þ g2 Þ; bX0 2

2

ð7Þ

2

and a140 ) b42b, a240 ) b sec y42bb44b ) y4p/3, where y ¼ |arg(l)|. The second part is proved similarly. To prove (v) if n ¼ 3, D(P)40, then Eq. (7) is valid. Now a1a2 ¼ a3 ) b2b+b(b2+g2) ¼ 2bb2 ) b ¼ 0 or 2 b +g2+b2 ¼ 2bb The last equality is not valid if both a140, a240. To prove (vi) use the fact that for general n " #" # Y Y ðl þ bj Þ ðl  bk  igk Þðl  bk þ igk Þ ) PðlÞ ¼ " an ¼

j

Y

#" bj

j

k

Y

#

ðb2k þ g2k Þ .

ð8Þ

k

To prove (vii) use Eq. (8) and P(l) ¼ P(l)8l ) P(l) contains only even power of l ) bj ¼ 0 8j; bk ¼ 08k ) Y Y ðl2 þ g2k Þ ¼ ðx þ g2k Þ. PðlÞ ¼ k

k

And all the roots x should be negative. To prove (viii) not that if P(z) has no roots in H the region |arg(l)|oap/2, hence the function 1/P(z) will be analytic in this region. Using Cauchy theorem C f ðzÞ dz ¼ 0 for all f(z) analytic within and on the curve C, and that P(z) is polynomial of degree 41 this completes the proof. & One can give explicit examples where the Routh–Hurwitz conditions are not valid yet Eq. (3) is satisfied for explicit a, e.g. a ¼ 12. The first example is l2 l 1 þ þ ¼ 0, 2 2 2     1 1 1 1 3 2 l  1  pffiffiffi l þ  pffiffiffi l þ pffiffiffi ¼ 0. 2 2 2 2 2 l3 

For n ¼ 3, one can solve the polynomial equation explicitly and apply Eq. (3) to the solutions. The solution method is: Define y ¼ la1/2, then the polynomial becomes y3 þ py þ q ¼ 0;

p ¼ a21 =3 þ a2 ; q ¼ 2a31 =27  a1 a2 =3 þ a3 ,

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y ¼ r þ s; r ¼

rffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffi qffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffi 3

ðq=2Þ þ

2

3

ðq=2Þ þ ðp=3Þ ; s ¼

611

rffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffi qffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffi 3

ðq=2Þ 

ðq=2Þ2 þ ðp=3Þ3 ,

choose the roots such that rs ¼ p/3. Conjecture 1. For all n43, if D1 ; D2 ; . . . ; Dn are Routh–Hurwitz determinants     a1 1 0      a1 1      D1 ¼ a1 ; D2 ¼  ; D3 ¼  a3 a2 a1 ; . . . ,    a3 a2   a5 a4 a3  then the conditions Di 40; i ¼ 1; 2; . . . ; n  2;

an 40;

Dn1 ¼ 0,

(9)

are sufficient conditions that Eq. (3) is valid for all aA[0, 1). This conjecture can be proved for n ¼ 4. The case n ¼ 3 is proved in Proposition 1. Now we apply Proposition 1 to derive the value of a at which chaos or instability disappears at some models. Fractional order Lotka-Volterra (FLV) predator–rey model is given by Da x ¼ bx  xy; Da y ¼ gy þ xy; a 2 ½0; 1, where b, g are positive constants. The equilibrium solutions of FLV are (0, 0) and (g, b). The eigenvalues corresponding to (0, 0) are p b, ffiffiffiffiffi g respectively hence (0, 0) is unstable for all aA[0, 1]. The eigenvalues corresponding to (g, b) are i bg hence |arg(l)| ¼ p/2, then it is locally asymptotically stable for all aA[0, 1). This agrees with the numerical results of Ref. [5]. Fractional order Chen (FOC) model is given by [7] Da x ¼ aðy  xÞ; Da y ¼ ðc  aÞx  xz þ cy; Da z ¼ xy  bz, where a ¼ 35, b ¼ 3, c ¼ 28. The equilibrium solutions for FOC are (0, 0, 0) and ðxn ; xn ; xn2 =bÞ, where pffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffi xn ¼  bð2c  aÞ. The eigenvalues of (0, 0, 0) are l ¼ b, l2+(ac)la(2ca) ¼ 0. Using Proposition 1 part (vi), then (0, 0, 0) is unstable for all aA[0, 1]. The eigenvalues of the internal equilibrium solution is l3+(ac+b)l2+bcl+2ab(2ca) ¼ 0. Since all the coefficients of this polynomial are positive and it is easy to check that D(P)o0, using Proposition 1 part (iv) then the internal solution of FOC will be stable for ao23 which is in excellent agreement with the numerical result obtained by and Chen [8]. A similar result is obtained for fractional order Lorenz system Da x ¼ cðy  xÞ; Da y ¼ rx  xz  y; Da z ¼ xy  bz, where r, b, c are positive constants and r41. The fractional order Rossler system (FOR) is defined by [9] Da x ¼ ðy þ zÞ; Da y ¼ x þ ay; Da z ¼ 0:2 þ xz  10z; a ¼ 0:6 pffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffi There are one equilibrium z ¼ y, x ¼ ay, y ¼ ½10 þ 100  0:8a=2a, and the characteristic polynomial is l3 þ ðay  a þ 10Þl2 þ ð1  ya2  10a  yÞl þ 10 þ 2ay ¼ 0. It is direct to see that a2o0, a140 hence by solving the characteristic equation directly one gets the following roots: l ¼ 9:986; l ¼ 0:3  0:954i; l ¼ 0:3 þ 0:954i. This implies that the equilibrium solution is locally asymptotically stable if ao0.8 which is in excellent agreement with the result obtained numerically in Ref. [9]: aA(0.7, 0.8).

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Considering the fractional order Chua model Da x ¼ aðy  xÞ  gðxÞ; Da y ¼ s½aðy  xÞ þ z, Da z ¼ cðy þ rzÞ, 8 if jxjo1; > < x ½1 þ bðjxj  1ÞsgnðxÞ if 1ojxjo10; gðxÞ ¼ > : ½10ðjxj  10Þ þ 9b  1sgnðxÞ if jxj410; where a ¼ 0.923 or 1, b ¼ 0.636, r ¼ 0.071 or 0, s ¼ 0.066. The equilibrium solution is xE7(1b)/(ab), yE0, zEax. Linearizing about the quilibrium solution one gets 2 3 a þ b a 0 6 7 sa s 5, 4 sa 0

c

rc

whose eigenvalues for a ¼ 1, b ¼ 0.636, c ¼ 0.779, s ¼ 0.066, r ¼ 0.071 are l ¼ 0.486, l ¼ 5  10470.184i which implies that this equilibrium is locally asymptotically stable for aA[0,1). The eigenvalues for a ¼ 0.923, b ¼ 0.636, c ¼ 0.779, s ¼ 0.066, r ¼ 0 are l ¼ 0.406, l ¼ 0.0297.188i which implies that this equilibrium is locally asymptotically stable for ao0.9.

3. Stability conditions for some fractional order differential coupled map lattices Spatial effects are important in many biological systems. Thus generalizing fractional order systems (FOS) to include them is important. The standard approach is fractional order partial differential equations. However since most biologically interesting systems are nonlinear [10], one gets fractional order nonlinear partial differential equations whose existence and uniqueness has not been established yet. Therefore, we use coupled map lattices (CML) [11] as an alternative approach to include spatial effects in FOS. Consider the 1-system CML Da ui ðtÞ ¼ ð1  DÞf ðui Þ þ i ¼ 1; 2; . . . ; n,

D ½ f ðuiþ1 Þ þ f ðui1 Þ, 2 ð10Þ

where D is a positive constant. The homogeneous equilibrium solution of Eq. (10) satisfies f(ueq) ¼ 0 and it is stable if all the eigenvalues of the circulant matrix [12] 3 2 ð1  DÞf 0 ðD=2Þf 0 0 ... 0 ðD=2Þf 0 7 6 ðD=2Þf ð1  DÞf 0 ðD=2Þf 0 ... 0 7 6 7 6 0 0 0 7 6 0 ðD=2Þf ð1  DÞf ðD=2Þf . . . 0 7 6 6 ... ... ... ... ... ... 7 5 4 0 0 0 0 ... 0 ðD=2Þf ð1  DÞf ðD=2Þf satisfies Eq. (2). Since the eigenvalues of the circulant matrices [12] are known, the local asymptotic stability conditions become      arg ð1  DÞf 0 ðueq Þ þ Df 0 ðueq Þ cos 2pk 4 ap ,  n  2 k ¼ 0; 1; . . . ; n  1

ð11Þ

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Generalizing to 2-system CML Da xi ¼ ð1  DÞf ðxj ; yj Þ i Dh f ðxjþ1 ; yjþ1 Þ þ f ðxj1 ; yj1 Þ , þ 2 Da yi ¼ ð1  DÞgðxj ; yj Þ i Dh gðxjþ1 ; yjþ1 Þ þ gðxj1 ; yj1 Þ , þ 2

ð12Þ

j ¼ 1, 2, y, n. The homogeneous equilibrium solutions are given by f(xeq, yeq) ¼ 0, g(xeq, yeq) ¼ 0 and is locally asymptotically stable if all the eigenvalues of the following matrix B satisfies Eq. (2): #   " qf =qx qf =qy D 2pk B ¼ ð1  DÞ þ cos , (13) qg=qx qg=qy 2 n where the Jacobian matrix is evaluated at the equilibrium point. 4. Application to a nonlocal epidemic model Now we present a nonlocal interacting epidemic model. The nonlocal interactions in the epidemic spreading is widely observed in many outbreaks, especially the recent ones of FMD, SARS and bird’s flu. The Lajmanovich-Yorke model [13,14] is a special case of coupled map lattices. It is a globally interacting model that emphasizes the diffusion of a disease from other infected farms beside its spread within the same farm. We have generalized it to the inhomogeneous case [15] and introduced it as an approximation for the epidemic spreading on small-world networks [15]. Consider n patches, where each one contains a certain number of individuals (say animals). In general these patches are not identical. Infection spreads from infected animals within the patch and due to those diffusing from other patches. The fractional order form of the model is given by X Da yi ¼ li yi ð1  yi Þ þ mi ð1  yi Þ yj  gi yi ; i ¼ 1; 2; . . . ; n, (14) jai

where yi is the number of infected individuals in the ith patch. The first term represents the infection within the patch with a rate li. The second term represents the effect of other patches both nearby and far away at a rate mi. The recovery rate is represented by gi. Since the effect of other patches (second term in Eq. (14)) is significantly smaller than the first one, we expect that mi5li. The disease is eradicated if yi ¼ 0, 8 i ¼ 1, 2, y, n. So the stability of this solution is studied. Using the same procedures in the previous section, the stability of the zero solution (disease free state) is that all the eigenvalues x of the matrix A satisfy |arg(x)|4ap/2 where 3 2 l1  g 1 m1 m1 :: m1 7 6 l2  g 2 m2 :: m2 7 6 m2 7 6 6 m3 m3 l3  g3 m3 m3 7 7 6 A¼6 7. :: :: :: :: 7 6 :: 7 6 6 :: :: :: :: :: 7 5 4 mn mn mn . . . ln  g n For n ¼ 2, the solutions yi ¼ 0, i ¼ 1, 2 are locally asymptotically stable if  0qffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffi1   ðl1  g1 þ l2  g2 Þ2  4½ðl1  g1 Þðl1  g1 Þ  m1 m2    1 tan @ A   l1  g 1 þ l2  g 2   ap 4 . 2

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For n ¼ 3, the characteristic polynomial of A is x3 þ a1 x2 þ a2 x þ a3 ¼ 0, where a1 ¼ ½l1  g1 þ l2  g2 þ l3  g3 , a2 ¼ ðl1  g1 Þðl2  g2 Þ  m1 m2 þ ðl1  g1 Þðl3  g3 Þ  m1 m3 þ ðl3  g3 Þðl2  g2 Þ  m3 m2 and a3 ¼ ½ðl1  g1 Þðl2  g2 Þðl3  g3 Þ þ 2m1 m2 m3  ðl1  g1 Þm2 m3  ðl3  g3 Þm2 m1  ðl2  g2 Þm1 m3 . Using part (vi) in Proposition 1, the disease free state is unstable if a3o0. Finally vaccination may affect the parameters li but not mi. Also it is important to know whether the vaccine works once administered or it takes time till it becomes effective. 5. Conclusions A fractional order evolution equation describing a random process with memory is concluded. This will be relevant to many complex adaptive systems. The stability conditions for both fractional order differential equations and fractional order differential coupled map lattices are derived. A fractional order form of Lajmanovich-Yorke model is introduced. This model emphasis the nonlocal interaction beside the local interaction in the epidemic spreading. Both types of interaction are widely observed in the recent FMD, SARS and bird’s flu outbreaks. Acknowledgment One of us (E. Ahmed) wishes to thank Prof. H. M. Yehia for discussions and help. References [1] [2] [3] [4] [5] [6] [7] [8] [9] [10] [11] [12] [13] [14] [15]

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